Filtration system

ABSTRACT

A filtration system is arranged to safely vent a storage room into which a fog mixture is introduced. Venting the storage room reduces and/or prevents a substantial increase in the internal pressure of the storage room. To control the pressure differential between the storage room and the ambient air pressure, a venting manifold with an in-line duct fan is used, for example, to exhaust storage room air into the atmosphere. The exhausted storage room air is filtered to reduce the exfiltration of chemicals and/or other contaminants from the environmentally sealed storage room.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 15/223,414 filed Jul. 29, 2016 which is a continuation of application Ser. No. 14/863,728, filed on Sep. 24, 2015, which is a continuation of patent application Ser. No. 13/566,936 filed Aug. 3, 2012, now abandoned.

BACKGROUND

Post-harvest chemicals are applied to fruit in environmentally sealed storage rooms. Air and treatment chemicals are applied in the form of a chemical fog mixture. The fog mixture is introduced into the storage room using a device such as an electro-thermofogger gun. The introduction of the externally supplied air in the fog mixture increases the internal pressure of the environmentally sealed storage rooms.

SUMMARY

This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended as an aid in determining the scope of the claimed subject matter.

A system and method is disclosed herein for safely venting a storage room (such as a commodity storage room) into which a fog mixture is introduced. Venting the storage room reduces and/or prevents a substantial increase in the internal pressure of the storage room. To control the pressure differential between the storage room and the ambient air pressure, a venting manifold with an in-line duct fan is used, for example, to exhaust storage room air into the atmosphere. The exhausted storage room air is filtered to reduce the exfiltration of chemicals and/or other contaminants from the environmentally sealed storage room.

These and other features and advantages will be apparent from a reading of the following detailed description and a review of the associated drawings. It is to be understood that both the foregoing general description and the following detailed description are explanatory only and are not restrictive. Among other things, the various embodiments described herein may be embodied as methods, devices, or a combination thereof. The disclosure herein is, therefore, not to be taken in a limiting sense.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic diagram illustrating a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 2 is an isometric view illustrating a filter system in accordance with embodiments of the present disclosure;

FIG. 3 is a plot diagram that illustrates the efficiency of a “3M” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 4 is a plot diagram that illustrates the efficiency of a “well-sealed 3M” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 5 is a plot diagram that illustrates the efficiency of a “cheap” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 6 is a plot diagram that illustrates the efficiency of a “reusable” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 7 is a plot diagram that illustrates the efficiency of a “cheap (2^(nd) test)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 8 is a plot diagram that illustrates the efficiency of a “reusable filters pretreated with propylene glycol” (PG) filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 9 is a plot diagram that illustrates the efficiency of a “carbon/fiber filter (untreated)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 10 is a plot diagram that illustrates the efficiency of a “carbon/fiber filter (10% PG)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 11 is a plot diagram that illustrates the efficiency of a “3M filter (Second Test)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 12 is a plot diagram that illustrates the efficiency of a “3M filter (washed and dried)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 13 is a plot diagram that illustrates the efficiency of a “two cheap and four 3M filters” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 14 is a plot diagram that illustrates the efficiency of a “two cheap and four 3M filters (reused)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 15 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (new)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 16 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (reused)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 17 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 EcoFOG)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 18 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 Melted DPA)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 19 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 new EcoFOG 100)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 20 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 new EcoFOG 100)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 21 is a plot diagram that illustrates the efficiency of a “six new 3M filters (EcoFOG 160)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure;

FIG. 22 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure; and

FIG. 23 is a plot diagram that illustrates the efficiency in a second test of a “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure.

DETAILED DESCRIPTION

Various embodiments will be described in detail with reference to the drawings, wherein like reference numerals represent like parts and assemblies throughout the several views. Many details of certain embodiments of the disclosure are set forth in the following description and accompanying figures so as to provide a thorough understanding of the embodiments. Reference to various embodiments does not limit the scope of the claims attached hereto. Additionally, any examples set forth in this specification are not intended to be limiting and merely set forth some of the many possible embodiments for the appended claims.

FIG. 1 is a schematic diagram illustrating a thermo-fogging filtration system in accordance with embodiments of the present disclosure. The thermofogging filtration system 100 includes an environmentally sealed storage room 110 (such as a commodity storage room for storing potatoes) is provided for safely treating items within the environmentally sealed storage room 110. The environmentally sealed storage room 110 is a substantially closed room that is arranged to substantially reduce the introduction of a substantial amount of treatment substances into the surrounding area.

Access to the chamber of the environmentally sealed storage room 110 can be provided using access port 112, which is arranged to allow ingress to and egress from the chamber of the environmentally sealed storage room 110 by, for example, humans and/or items 124 to be treated within the environmentally sealed storage room 110. (In various embodiments, the environmentally sealed storage room 110 is any suitable chamber that need not be large enough to allow a human to enter the environmentally sealed storage room 110.)

An airstream substance infuser is arranged to infuse treatment substances into an airstream to generate air-borne treatment substances. The airstream substance infuser is arranged to introduce the airstream and the air-borne treatment substances into the volume of air of the substantially closed room to generate dispersed air-borne substances. Thermo-fogging gun 120 is an example of an airstream substance infuser that is arranged to infuse treatment substances into an airstream. Thermo-fogging gun 120 is coupled to the environmentally sealed storage room 100 via access port 112, which is normally sealed during times in which items 124 within the environmentally sealed storage room 110 are being treated. During treatment, air-borne substances 122 are introduced into the environmentally sealed storage room 110 by directing the airstream through an exhaust port of the thermo-fogging gun 120. The air-borne substances 122 disperse after being introduced into the environmentally sealed storage room 110 and come in contact with the items 124 that are to be treated.

In an example application, post-harvest chemicals are applied to fruit (or vegetables, including tubers such as potatoes) in sealed storage rooms using a thermo-fogging application method. Air and treatment chemicals in a form such as fog is introduced into a storage room (and/or container) using an electrically driven thermo-fogging gun. The treatment chemicals are dispersed in the storage room using air currents (such as those caused by the thermo-fogging gun itself and/or circulation fans) and (e.g., naturally occurring) diffusion gradients. (The term “fan” means, for example, a device that causes movement of air.) The operation is can be continued (without, for example, interruption) over a period of hours (more or less).

However, the introduction of air-borne substances 122 into the environmentally sealed storage room 110 can increase the air pressure of the environmentally sealed storage room 110. For example, the rise in the air pressure of the environmentally sealed storage room 110 can potentially cause exfiltration of air (and air-borne particles) from the environmentally sealed storage room 110 in accordance with the degree to which the environmentally sealed storage room 110 is, inter alia, airtight. Also, the rise in the air pressure of the environmentally sealed storage room 110 can cause a higher back-pressure to exist relative to the exhaust port of the thermo-fogging gun 120, which can cause a reduction in the efficiency of the thermo-fogging gun as well as a reduction in the efficacy of the air-borne substances 122 treatment process.

An exhaust manifold 140 is provided to prevent a substantial increase in the air pressure of the environmentally sealed storage room 110 (so that, for example, uncontrolled exfiltration is reduced and/or eliminated). In an example embodiment, the exhaust manifold 140 is a plastic tube that is arranged in an area of the environmentally sealed storage room 110 that is at an opposite end of and/or away from the area of the access port 112 such that the air-borne substances traverse a portion of the environmentally sealed storage room 110 that includes items 124 to be treated.

Vent holes 142 are arranged in the exhaust manifold 140 to permit the introduction of air (including air-borne particles) into the exhaust manifold 140. In an example embodiment, the vent holes 142 are three/quarters of an inch in diameter and are spaced on 18 inch centers along a wall of the environmentally sealed storage room 110 that faces the exhaust port of the thermo-fogging gun 120. The air pressure developed in the environmentally sealed storage room 110 by the introduction of the air (that conveys the air-borne substances) into the environmentally sealed storage room 110 facilitates the introduction of air (including air-borne particles) into the exhaust manifold 140. The distributed arrangement of the vent holes 142 along portions of the exhaust manifold 140 (placed along the wall that opposes the exhaust port 112 through which the air-borne substances 122 are introduced into the environmentally sealed storage room 110, for example) promotes a more even dispersion of the air-borne substances throughout the chamber of the environmentally sealed storage room 110.

The exhaust manifold 140 is coupled to a filter 150 that is arranged to capture a portion (including a portion containing substantially all) of the concentration of air-borne particles that have been introduced into the exhaust manifold 140. The filter 150 can be located outside of the environmentally sealed storage room so as to permit easy maintenance and monitoring of the filter 150. (Filter 150 is further described below with reference to FIG. 2.)

To reduce the possibility of exfiltration of air-borne particles from filter 150 (and/or portions of the exhaust manifold 140 that are external to be environmentally sealed storage room 110), and in-line duct fan 160 is coupled to the exhaust of filter 150. In-line duct fan 160 is arranged to provide a negative pressure (e.g., suction) to the exhaustive filter 150. The applied negative pressure can, for example, be used to reduce the pressure of the filter 150 relative to the ambient air pressure (e.g., the air pressure surrounding the environmentally sealed storage room 110).

The reduced internal pressure of filter 150 substantially reduces the potential for the air-borne substances to escape from the filter 150 housing by lessening (and/or even reversing) the pressure gradient between the inside of filter 150 and the outside of filter 150. (As described below, the housing of filter 150 is arranged to be opened to permit maintenance of the filter 150 as well as to permit inspections thereof) The exhaust of in-line duct fan 160 can be, for example, optionally coupled to another filter and/or installed in series either before or after the filter 150. The exhaust of in-line duct fan 160 can be released as exhaust (through exhaust vent 170) to the ambient air (surrounding environmentally sealed storage room 110). Exhaust vent 170 optionally contains a check valve 172 to, for example, permit portions of the system (as described below) to operate at pressures lower than ambient (e.g., gauge) pressure (which normally reduces the possibility of exfiltration of treatment substances into the ambient air).

In an embodiment, the thermo-fogger gun 120 is arranged to introduce around 30-40 cubic feet per minute (CFM) of an air/chemical mixture into the environmentally sealed storage room 110 in the form of a fog. Controller 180 is arranged to determine ambient pressure (via sensor 182), chamber pressure (via sensor 132), filter intake pressure (via sensor 152), filter exhaust pressure (via sensor 154), and fan exhaust pressure (via sensor 162).

Controller 180 is arranged to control the storage room pressure to a selected value between (for example) −0.15 and +0.15 inches water column (IWC) using a differential pressure reading. The differential pressure reading can be determined by subtracting a reading from sensor 132 with a (nearly contemporaneous) reading from sensor 182. Controller 180 is arranged to control the storage room pressure to a selected value used to control a variable speed in-line duct fan.

Controller 180 can also determine a flow rate through the filter 150 by determining a differential pressure in response to readings from sensor 152 (at the intake of filter 150) and from sensor 154 (at the exhaust of filter 150). An abnormally high pressure differential can indicate a clogged filter (for example) or indicate that service of the filter is to be performed. Pressure sensor 162 can be used in combination other pressure sensors (such as sensor 154) to determine the efficiency of in-line duct fan 160, a blockage of the exhaust manifold upstream or downstream of the sensor 162, and normalization and/or calibration of other sensors.

In various embodiments, controller 180 is optionally arranged to selectively couple one (or more simultaneously) of intakes 182, 184, and 186 to the gun intake 188. When intake 182 is selected, air from the volume of air (including air-borne treatment substances, if any) from environmentally sealed room 110 can be recirculated for injection of additional air-borne treatment substances into the environmentally sealed room. Recirculation via intake 182, for example, extends the life of filter 150, and reduces the possibility that the air-borne substances (not captured by filter 150) might be released to the surrounding area.

When intake 184 is selected, air exhausted from the filter 150 (including air-borne treatment substances, if any) can be recirculated for injection of additional air-borne treatment substances into the environmentally sealed room. Using information from (pressure) sensors 132, 152, 154, 162, and 182, the controller 180 can vary the pressure in selected areas. The pressure of the volumes measured by sensors 152, 154, and 162 can be controlled by selectively controlling the relative speeds of an intake fan of gun 120 and fan 160.

When the flow rate of the fan 160 is increased over the flow rate of the fan of gun 120, the air pressures in between the exhaust of gun 120 and the intake of fan are lowered. Thus, the pressures at points measured by sensors 152, 154, and 162 can be reduced—even to pressures below ambient pressure (which reduces the possibility of exfiltration of the treatment substances to the ambient air). The pressure of the volumes measured by sensors 152, 154, and 162 can be controlled by selectively controlling the relative speed of one or both of fan of gun 120 and fan 160. To help maintain operation of the gun 120 and fan 160 with normal operational parameters, intake 186 (for example) can be selectively opened using a range of settings from a fully open to a fully closed position. (In another exemplary embodiment, check valve 172 can be controlled in a similar fashion).

Recirculation via intake 184 when the flow rate of gun 120 is increased over the flow rate of the fan 160 and check valve 172 is closed (via controller 180, or relative air pressures, for example), reduces the possibility that the air-borne substances (not captured by filter 150) might be released to the surrounding area during a fogging process.

When intake 184 is selected, ambient air is used for by the gun 120 for injection of additional air-borne treatment substances into the environmentally sealed room. The fan 160 is used to motivate air flow in the exhaust manifold, to draw the air-borne substances through filter 150, and to exhaust the filtered air through vent 170 as described above.

Accordingly, the possibility of exfiltration of air-borne substances from the environmentally sealed storage room 110 is reduced, the possibility of exfiltration of air-borne substances from portions of the exhaust manifold 140 and filter 150 is reduced, and the dispersion of the air-borne substances in the environmentally sealed storage room 110 is more evenly distributed in accordance with the distribution of vent holes 142.

FIG. 2 is an isometric view illustrating a filter system in accordance with embodiments of the present disclosure. The filter system 200 includes a chamber 210 having a width W (e.g., 16 inches), a height H (e.g., 25 inches), and a depth D (e.g., 20 inches). Intake port 220 is arranged to accept an air current 222, which contains air-borne substances that are to be filtered (e.g., removed) by filter system 200. Thus the air current 222 is coupled to chamber 210 via intake port 220, and after being filtered as described below, is exhausted via exhaust port 250. Fan 260 is arranged to motivate the passage of air current 222 through filters of the chamber 210 by evacuating air (in varying degrees as described above) from the chamber 110 and exhausting the evacuated air as air current 272.

Chamber 210 has a first stage filter 230 and a second stage filter 240. The first stage filter 230 in an embodiment is a bank of six “3M” high particle-rated fiber air filters (such as model number 1900 or 2200 and having dimensions of one inch deep by 20 inches wide by 25 inches high) that are arranged in series with respect to the air current flow (such that the air current passes through each fiber air filter in the bank in turn). The first stage filter 230 includes, for example, a series (bank) of pleated fiber filters that are arranged to filter out “visible” air-borne particles. The air-borne particles typically include an active ingredient (AI) used for treating, for example, the items 124 in the environmentally sealed storage room. The first stage filter 230 can include one or more individual filters arranged in a bank.

The second stage filter 240 in an embodiment is a column activated carbon 12×30 mesh (e.g., 1.68 mm×0.595 mm) filter (having outer dimensions of two inches deep by 20 inches wide by 25 inches high). The second stage filter 240 is arranged to capture volatile solvents and odor (“non-visible” air-borne particles) present in the air current 222. The second stage filter 240 can include one or more individual filters arranged in a bank.

The efficiency of the filter system 200 can be made by performing measurements on the quality of the intake air as well as performing measurements on the quality of the exhaust (e.g., filtered) air. In an embodiment, inspection ports 224 and 254 are respectively provided to, for example, to sample the intake air and the exhaust air. The inspection ports 224 and 254 are used to provide a substantially airtight aperture that is arranged to accept a sampling probe. For example the inspection ports 224 and 254 can each include a substantially sealed membrane through which a needle of syringes 226 and 256 is respectively inserted. (The terms “substantially” sealed or airtight are used, for example, to indicate a level at which exfiltration of air-borne substances and/or infiltration of air from the sampling ports would introduce an unacceptable level of error in the measurements.)

Measurements on the quality of the intake air and exhaust air can be performed by measuring by sampling the concentrations of active ingredient (AI) pre-filter (e.g., via inspection port 224) and post-filter (e.g., via inspection port 254). Concentration measurements can be performed by taking aerosol samples at intervals starting, for example, around five to 10 minutes after the beginning of the fogging process (which typically includes introducing treatment substances into the environmentally sealed storage room 110 as described above). In an exemplary embodiment, a first 60 ml-syringe is used to draw a 50 ml sample via inspection port 224 (pre-filter) and a second 60 ml-syringes is used to draw a 50 ml sample via inspection port 254 (post-filter).

A 50 ml sample can be drawn by insert the needle into an inspection port and the plunger slowly drawn back (e.g., pulled up) to the 60 ml mark. After a 10 second delay, the plunger is depressed (e.g., pushed down) to 50 ml mark. The syringe is extracted from the inspection port and used to draw 5 ml of a solvent (such as analytical grade ethyl acetate) into the syringe. The aerosol sample and the solvent are mixed by, for example, removing the needle, capping the syringe outlet, and vigorously shaking the syringe for around 30 seconds. After a 15 second delay (while keeping the syringe vertically oriented with the outlet still capped), the plunger depressed to expel the liquid content (include solvent and solutes) into sampling vials. The level of the active ingredient content of the liquid content in the sampling vials can be determined using a suitable gas chromatography- (GC-) based method.

The efficiency of the filter can be determined by comparing the higher concentration of AI in the pre-filter aerosol sample with the (usually lower) concentration (if any) of AI in a corresponding post-filter aerosol sample. For more accurate determinations, the samples are to be drawn contemporaneously (or substantially contemporaneously) compared to the corresponding outlet sample. The determination can be expressed in accordance with: Cg=100×CL  (I) where Cg is the concentration of AI in the aerosol (expressed in units of mg/m³) and where CL is the concentration of AI in the liquid solution as determined by the gas chromatography measurement (expressed in units of mg/L or ppm).

Table 1 is a summary of capture efficiencies of various filters tested:

TABLE 1 AI (mg)/ AI (mg)/ AI (mg)/ Wgt m{circumflex over ( )}3 m{circumflex over ( )}3 m{circumflex over ( )}3 AI reduction AI reduction AI reduction gain Filter Material AI min max avg min % max % avg % (g) (6) 20″ × 25″ 3M 2200 air filters + 2″ carbon pyrimethanil 0 0 0 100 100 100 1074 (6) 20″ × 25″ 3M 2200 air filters + 2″ carbon pyrimethanil 0 0 0 100 100 100 1121 (6) 20″ × 25″ 3M 1900 rated fiber air filter DPA 0.1 7.7 4 99.7 100 99.85 266 (6) 20″ × 25″ 3M 1900 rated fiber air filter pyrimethanil 1 9 4 99.3 99.8 99.6 497 (6) 20″ × 25″ 3M 1900 rated fiber air filter *after 1 pyrimethanil 3 33 13 90.6 99.4 97 room* (6) 3M 1900 rated fiber air filter (“Merv 13”) pyrimethanil 55.9 191.2 95.3 94.1 98.2 96.9 1201 (6) 20″ × 25″ 3M 1900 rated fiber air filter DPA 0 21.8 6.7 63.6 100 93.3 1121 (2) low cost fiber filter + (4) 3M 1900 pyrimethanil 40 80 54 82.8 95.8 92.4 784 (6) 20″ × 25″ 3M 1900 rated fiber air filter *after pyrimethanil 5 276 72.7 67.8 98.8 91.5 787 2nd room* (6) 20″ × 25″ 3M 1900 rated fiber air filter pyrimethanil 40 60 50 81 98.1 89.2 1021 (6) re-used 20″ × 25″ 3M 1900 rated fiber air filter pyrimethanil 70 160 117.5 83 92.3 86.2 866 6″ bed Activated coconut carbon-12 × 30 Mesh- pyrimethanil 30 920 256 57 96.2 84 748 Pretreated 10% propylene glycol (6) 20″ × 25″ 3M 1900 rated fiber air filter DPA 128 175 143.4 67 86.5 82 397 (6) 3M 1900 rated fiber air filter (“Merv 13”) pyrimethanil 90 230 146 58.3 92.5 81.8 901 washed and dried (6) 3M 1900 rated fiber air filter (“Merv 13”) *2nd pyrimethanil 40 130 88 50 91.8 80.3 1143 test* 6″ bed activated coconut carbon-12 × 30 Mesh- pyrimethanil 40 580 166 24.7 97 79.7 934 (2) low cost fiber filter + (4) reused 3M 1900 pyrimethanil 60 510 222 45.7 88.7 78.5 658 (6) combo carbon/fiber air filters pretreated with pyrimethanil 120 1740 670 48.1 74.1 58.3 284 10% propylene glycol (6) Low cost fiber filter-600 particle rating pyrimethanil 50 2600 766.7 −18 89.5 56.2 426 (6) Reusable fiber/sponge filter (“Merv 6”) pyrimethanil 190 1840 898 18.9 88.6 52.8 372 pretreated with 10% propylene glycol “BPL” coarse 4 × 6 mesh carbon 6″ bed pyrimethanil 90 880 370 3.3 82.5 51 853 (6) reusable fiber/sponge filter (“Merv 6”) pyrimethanil 210 1641 941.7 13.1 59.2 41.78 367 (6) combination carbon/fiber air filters pyrimethanil 150 1730 666 27.8 54.4 40.9 304 “BPL” coarse 4 × 6 mesh carbon 12″ bed pyrimethanil 60 780 285 0 40.6 16 839

In an embodiment, the present invention is directed to methods for filtration, comprising arranging fruits and/or vegetables in a substantially closed room having a volume of air, introducing pyrimethanil, and optionally, additional treatment substances, into an airstream with a thermofogger gun to generate air-borne treatment substances at a rate of up to 40 cubic feet per minute, introducing the airstream and the air-borne treatment substances into the volume of air of the substantially closed room to generate the dispersed air-borne substances, creating with a fan a pressure between −0.15 and 0 inches water column upon a bank of six high particle-rated pleated fiber filters, and inducing an exhaust air current that flows from the substantially closed room into an exhaust port of the substantially closed room, wherein the exhaust air current includes the air-borne substances from the exhaust port and the filter bank captures around 95 percent of the air-borne treatment substances.

FIG. 3 is a plot diagram that illustrates the efficiency of a “3M” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 300 includes a plot 310, which illustrate a percentage of weight gain of each “3M” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 45 minutes.

Table 2 is a summary of the weight gain of the “3M” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 2 Filters Weight (g) # Before After Δ m % W. Gain 1 275.98 730.5 454.52 164.7 2 278.19 509.29 231.1 83.1 3 271.49 415.21 143.72 52.9 4 271.21 374.49 103.28 38.1 5 271.16 339.58 68.42 25.2 6 271.12 306.63 35.51 13.1 Total 1639.15 2675.7 1036.55 63.2 Table 3 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “3M” filters tested:

TABLE 3 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction  5 min 508.83 24.32 21 times 95.2 25 min 4891.2 452.969 11 times 90.7

FIG. 4 is a plot diagram that illustrates the efficiency of a “well-sealed 3M” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 400 includes a plot 410, which illustrate a percentage of weight gain of each “well-sealed 3M” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 135 minutes.

Table 4 is a summary of the weight gain of the “well-sealed 3M” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 4 Filters Weight (g) # Before After Δ m % W. Gain 1 274.53 768.15 493.62 179.8 2 273.94 536.91 262.97 96.0 3 275.63 454.37 178.74 64.8 4 275.68 398.83 123.15 44.7 5 271.67 362.18 90.51 33.3 6 272.15 324.3 52.15 19.2 Total 1643.6 2844.74 1201.14 73.1 Table 5 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “well-sealed 3M” filters tested:

TABLE 5 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction  5 min 4311.0 113.7 37.9 97.4 10 min 3610.8 72.6 49.8 98.0 20 min 4010.0 71.4 56.1 98.2 35 min 3244.4 191.2 17.0 94.1 70 min 2521.3 55.9 45.1 97.8 125 min  1592.1 67.2 23.7 95.8

FIG. 5 is a plot diagram that illustrates the efficiency of a “cheap” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 500 includes a plot 510, which illustrate a percentage of weight gain of each “cheap” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 15 minutes.

Table 6 is a summary of the weight gain of the “cheap” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 6 Filters Weight (g) # Before After Δm % W. Gain 1 130.67 131.3 0.63 0.5 2 131.32 132.39 1.07 0.8 3 134.52 131.43 0.91 0.7 4 130.9 131.8 0.9 0.7 5 130.14 130.64 0.5 0.4 6 131.09 131.8 0.71 0.5 Total 784.64 789.36 4.72 0.6 Table 7 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “cheap” filters tested:

TABLE 7 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 min 787.7 735.4 1.1 6.6

FIG. 6 is a plot diagram that illustrates the efficiency of a “reusable” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 600 includes a plot 610, which illustrate a percentage of weight gain of each “reusable” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 165 minutes.

Table 8 is a summary of the weight gain of the “reusable” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 8 Filters Weight (g) # Before After Δm % W. Gain 1 581.56 749.52 167.96 28.9 2 584.4 631.4 47 8.0 3 584.07 623.05 38.98 6.7 4 579.89 618.92 39.03 6.7 5 580.45 616.72 36.27 6.2 6 583.79 622.38 38.59 6.6 Total 3494.16 3861.99 367.83 10.5 Table 9 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “reusable” filters tested:

TABLE 9 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 1889.9 1641.4 1.2 13.1 20 2989.2 1516.9 2.0 49.3 50 1985.5 810.4 2.5 59.2 95 750 530 1.4 29.3 155 500 210 2.4 58.0

FIG. 7 is a plot diagram that illustrates the efficiency of a “cheap (2^(nd) test)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 700 includes a plot 710, which illustrate a percentage of weight gain of each “cheap (2^(nd) test)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 152 minutes.

Table 10 is a summary of the weight gain of the “cheap (2^(nd) test)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 10 Filters Weight (g) # Before After Δm % W. Gain 1 126.59 328.27 201.68 159.3 2 125.07 224.5 99.43 79.5 3 126.65 170.16 43.51 34.4 4 125.06 154.4 29.34 23.5 5 129.27 158.1 28.83 22.3 6 122.5 145.96 23.46 19.2 Total 755.14 1181.39 426.25 56.4 Table 11 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “cheap (2^(nd) test)” filters tested:

TABLE 11 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 7 2784 2600 1.1 6.6 27 1332 1570 0.8 −17.9 47 1715 180 9.5 89.5 72 1203 130 9.3 89.2 112 491 70 7.0 85.7 142 315 50 6.3 84.1

FIG. 8 is a plot diagram that illustrates the efficiency of a “reusable filters pretreated with propylene glycol” (PG) filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 800 includes a plot 810, which illustrate a percentage of weight gain of each “reusable filters pretreated with PG” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 165 minutes.

Table 12 is a summary of the weight gain of the “reusable filters pretreated with PG” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 12 Filters Weight (g) # Before After Δm PG on fltr % W. Gain 1 643.65 800.4 156.75 48.91 19.6 2 642.81 677.4 34.59 54.78 5.1 3 619.7 671.75 52.05 34.1 7.7 4 627.5 655.07 27.57 94.7 4.2 5 629.3 683.96 54.66 45.7 8.0 6 643.95 690.3 46.35 58.22 6.7 Total 3806.91 4178.88 371.97 336.41 8.9 Table 13 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “reusable filters pretreated with PG” filters tested:

TABLE 13 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 1220 990 1.2 18.9 25 2550 1840 1.4 27.8 45 2330 970 2.4 58.4 85 1690 50D 3.4 70.4 145 1660 19D 8.7 88.6

The efficiency of an “activated carbon six inches” filter used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure is now discussed. Tables 14 and 15 illustrate measurements taken when using an “activated carbon six inches” filter (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 14 is a summary of the weight gain of the “activated carbon six inches” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 14 Filters Weight (g) # Before After Δm % W. Gain 1 20411.7 21346.1 934.4 4.6 Total 20411.7 21346.1 934.4 4.6 Table 15 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “activated carbon six inches” filters tested:

TABLE 15 Aerosol Analysis Sampling Pre- After- AI Time Filter mg Filter mg Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 770 580 1.3 24.7 35 3030 90 33.7 97.0 65 1940 70 27.7 96.4 95 770 40 19.3 94.8 125 350 50 7.0 85.7

The efficiency of an “activated carbon six inches (pretreated)” filter used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure is now discussed. The activated carbon six inches filter was pretreated with a 10% solution of PG. Tables 16 and 17 illustrate measurements taken when using an “activated carbon six inches (pretreated)” filter (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 16 is a summary of the weight gain of the “activated carbon six inches (pretreated)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 16 Filters Weight (g) # Before After Δm % W. Gain 1 23586.8 24335.2 748.4 3.2 Tot 23586.B 24335.2 748.4 3.2 Table 17 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “activated carbon six inches (pretreated)” filters tested:

TABLE 17 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 2140 920 2.3 57.0 35 1830 230 8.0 87.4 65 1310 50 26.2 96.2 95 540 50 10.8 90.7 125 260 30 8.7 88.5

FIG. 9 is a plot diagram that illustrates the efficiency of a “carbon/fiber filter (untreated)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 900 includes a plot 910, which illustrate a percentage of weight gain of each “carbon/fiber filter (untreated)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 18 is a summary of the weight gain of the “carbon/fiber filter (untreated)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 18 Filters Weight (g) # Before After Δm % W. Gain 1 239.73 417.67 177.94 74.2 2 240.6 271.39 30.79 12.8 3 239.56 265.13 25.57 10.7 4 244.23 268.52 24.29 9.9 5 238.55 260.86 22.31 9.4 6 237.39 260.61 23.22 9.8 Total 1440.06 1744.18 304.12 21.1 Table 19 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “carbon/fiber filter (untreated)” filters tested:

TABLE 19 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 180 130 1.4 27.8 35 3090 1730 1.8 44.0 65 2060 940 2.2 54.4 95 640 380 0.6 40.6 125 240 150 1.6 37.5

FIG. 10 is a plot diagram that illustrates the efficiency of a “carbon/fiber filter (10% PG)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1000 includes a plot 1010, which illustrate a percentage of weight gain of each “carbon/fiber filter (10% PG)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 20 is a summary of the weight gain of the “carbon/fiber filter (10% PG)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 20 Filters Weight (g) # Before After Δm % W. Gain 1 261.2 421.31 160.11 61.3 2 263.74 291.9 28.16 10.7 3 264.44 289.9 25.46 9.6 4 265.11 288.31 23.2 8.8 5 264.13 285.17 21.04 8.0 6 269.35 295.75 26.4 9.8 Total 1587.97 1872.34 284.37 17.9 Table 21 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “carbon/fiber filter (10% PG)” filters tested:

TABLE 21 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 580 150 3.9 74.1 35 3490 1740 2.0 50.1 65 2060 940 2.2 54.4 95 770 400 1.9 48.1 125 340 120 2.8 64.7

FIG. 11 is a plot diagram that illustrates the efficiency of a “3M filter (Second Test)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1100 includes a plot 1110, which illustrate a percentage of weight gain of each “3M filter (Second Test)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 140 minutes.

Table 22 is a summary of the weight gain of the “3M filter (Second Test)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 22 Filters Weight (g) # Before After Δ m % W. Gain 1 273.13 722.62 449.49 164.6 2 271.97 522.04 250.07 91.9 3 274.07 452.04 177.97 64.9 4 2737 409.77 136.07 49.7 5 271.01 355.75 84.74 31.3 6 271.08 315.8 44.72 16.5 Total 1634.96 2778.02 1143.06 69.9 Table 23 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “3M filter (Second Test)” filters tested:

TABLE 23 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 970 80 12.1 91.8 35 1530 130 11.8 91.5 65 1120 90 12.4 92.0 95 340 110 3.1 67.6 125 160 80 2.0 50.0 135 360 40 9.0 88.9

FIG. 12 is a plot diagram that illustrates the efficiency of a “3M filter (washed and dried)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1100 includes a plot 1110, which illustrate a percentage of weight gain of each “3M filter (washed and dried)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 24 is a summary of the weight gain of the “3M filter (washed and dried)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 24 Filters Weight (g) # Before After Δ m % W. Gain 1 276.45 701.69 425.24 153.8 2 290.66 466.66 176 60.6 3 295 417.88 122.86 41.7 4 299.72 384.53 84.81 28.3 5 313.3 375.82 62.52 20.0 6 375.2 404.6 29.4 7.8 Total 1850.33 2751.18 900.85 48.7 Table 25 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “3M filter (washed and dried)” filters tested:

TABLE 25 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 520 90 5.8 82.7 35 2200 230 9.6 89.5 65 1870 140 13.4 92.5 95 860 120 7.2 86.0 125 360 150 2.4 58.3

FIG. 13 is a plot diagram that illustrates the efficiency of a “two cheap and four 3M filters” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1300 includes a plot 1310, which illustrate a percentage of weight gain of each “two cheap and four 3M filters” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 26 is a summary of the weight gain of the “two cheap and four 3M filters” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 26 Filters Weight (g) # Before After Δ m % W. Gain 1 126.42 311.21 184.79 146.2 2 123.35 290.91 167.56 135.8 3 274.17 447.07 172.9 63.1 4 275.67 402.02 126.35 45.8 5 276.46 360.24 83.78 30.3 6 276.33 324.74 48.41 17.5 Total 1352.4 2136.19 783.79 58.0 Table 27 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “two cheap and four 3M filters” filters tested:

TABLE 27 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 1790 80 22.4 95.5 35 1330 60 22.2 95.5 65 950 40 23.8 95.8 95 290 50 5.8 82.8 125 540 40 13.5 92.6

FIG. 14 is a plot diagram that illustrates the efficiency of a “two cheap and four 3M filters (reused)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1400 includes a plot 1410, which illustrate a percentage of weight gain of each “two cheap and four 3M filters (reused)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 28 is a summary of the weight gain of the “two cheap and four 3M filters (reused)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 28 Filters Weight (g) # Before After Δ m % W. Gain 1 123.26 316.59 193.33 156.8 2 130.54 274.26 143.72 110.1 3 324.74 468.45 143.71 44.3 4 360.24 449.26 89.02 24.7 5 402.02 453.92 51.9 12.9 6 447.07 483.53 36.46 8.2 Total 1787.87 2446.01 658.14 36.8 Table 29 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “two cheap and four 3M filters (reused)” filters tested:

TABLE 29 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 940 510 1.8 45.7 35 2740 390 7.0 85.8 65 640 80 8.0 87.5 95 620 70 8.9 88.7 125 400 60 6.7 85.0

FIG. 15 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (new)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1500 includes a plot 1510, which illustrate a percentage of weight gain of each “20×25 3M filters (new)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 30 is a summary of the weight gain of the “20×25 3M filters (new)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 30 Filters Weight (g) # Before After Δ m % W. Gain 1 302.25 751 448.75 148.5 2 301.82 556.5 254.68 84.4 3 339.90 532.35 192.54 56.6 4 301.25 385.84 84.59 28.1 5 303.84 332.1 28.26 9.3 6 302.92 315.63 12.71 4.2 Total 1851.98 2873.42 1021.44 55.2 Table 31 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (new)” filters tested:

TABLE 31 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 960 50 19.2 94.8 35 2100 40 52.5 98.1 65 480 60 8.0 87.5 95 390 60 6.5 84.6 125 210 40 5.3 81.0

FIG. 16 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (reused)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1600 includes a plot 1610, which illustrate a percentage of weight gain of each “20×25 3M filters (reused)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 100 minutes.

Table 32 is a summary of the weight gain of the “20×25 3M filters (reused)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 32 Filters Weight (g) # Before After Δ m % W. Gain 1 315.63 759.3 443.67 140.6 2 332.1 575.72 243.62 73.4 3 385.84 592.72 206.88 53.6 4 532.35 501.64 −30.71 −5.8 5 556.5 559.66 3.16 0.6 6 751 750.17 −0.83 −0.1 Total 2873.42 3739.21 865.79 30.1 Table 33 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (reused)” filters tested:

TABLE 33 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 500 70 7.1 86.0 35 2090 160 13.1 92.3 65 880 150 5.9 83.0 95 540 90 6.0 83.3

The efficiency of an “activated carbon (large granules) 20×20×6” filter used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure is now discussed. Tables 34 and 35 illustrate measurements taken when using an “activated carbon (large granules) 20×20×6” filter (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 34 is a summary of the weight gain of the “activated carbon (large granules) 20×20×6” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 34 Filters Weight (g) # Before After Δ m % W. Gain 1 17345.37 18198.1 852.8 4.9 Total 17345.4 18198.1 852.8 4.9 Table 35 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “activated carbon (large granules) 20×20×6” filters tested:

TABLE 35 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 910 880 1.0 3.3 35 2110 400 5.3 81.0 65 1370 240 5.7 82.5 95 430 240 1.8 44.2 125 160 90 1.8 43.8

The efficiency of an “activated carbon (large granules) 20×20×12” filter used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure is now discussed. Tables 36 and 37 illustrate measurements taken when using an “activated carbon (large granules) 20×20×12” filter (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 205 minutes.

Table 36 is a summary of the weight gain of the “activated carbon (large granules) 20×20×12” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 36 Filters Weight (g) # Before After Δ m % W. Gain 1 55905.26 56744.4 839.1 1.5 Total 55905.3 56744.4 839.1 1.5 Table 37 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “activated carbon (large granules) 20×20×12” filters tested:

TABLE 37 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 1080 780 1.4 27.8 45 520 460 1.1 11.5 85 320 190 1.7 40.6 125 130 120 1.1 7.7 165 110 100 1.1 9.1 205 60 60 1.0 0.0

FIG. 17 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 EcoFOG 100)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1700 includes a plot 1710, which illustrate a percentage of weight gain of each “20×25 3M filters (1900 EcoFOG 100)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 38 is a summary of the weight gain of the “20×25 3M filters (1900 EcoFOG 100)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 38 Filters Weight (g) # Before After Δ m % W. Gain 1 338.35 971.6 633.25 187.2 2 313.66 577.78 264.12 84.2 3 311.55 444.85 133.3 42.8 4 311.76 367.11 55.35 17.8 5 298.76 316.28 17.52 5.9 6 302.62 320.26 17.64 5.8 Total 1876.7 2997.88 1121.18 59.7 Table 39 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (1900 EcoFOG 100)” filters tested:

TABLE 39 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) DPA/M³ DPA/M³ (Times) Reduction 5 734.40 0 734.0 100.0 35 3369.0 21.8 154.9 99.4 65 938.0 5.0 188.0 99.5 95 173.5 4.4 39.0 97.4 125 125.3 0.0 125.3 100.0 155 24.31 8.8 2.7 63.6

FIG. 18 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 Melted DPA)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1800 includes a plot 1810, which illustrate a percentage of weight gain of each “20×25 3M filters (1900 Melted DPA)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 40 is a summary of the weight gain of the “20×25 3M filters (1900 Melted DPA)” filters tested (due to air-borne substances being captured by each filter, for example):

TABLE 40 Filters Weight (g) # Before After Δ m % W. Gain 1 308.43 494.29 185.86 60.3 2 307.78 365.9 58.12 18.9 3 303.5 321.56 18.06 6.0 4 305.73 308.84 3.11 1.0 5 308.2 308.98 0.78 0.3 6 307.2 307.61 0.41 0.1 Total 1840.84 2107.18 266.34 14.5 Table 41 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (1900 Melted DPA)” filters tested:

TABLE 41 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) DPA/M³ DPA/M³ (Times) Reduction 5 850 1.85 459.5 99.8 35 3740 10 374.0 99.7 65 3120 7.74 403.1 99.8 95 1950 0.1 19500.0 100.0 125 760 0.1 7600.0 100.0

FIG. 19 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 new EcoFOG 100)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 1900 includes a plot 1910, which illustrate a percentage of weight gain of each “20×25 3M filters (1900 new EcoFOG 100)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 119 minutes.

Table 42 is a summary of the weight gain of the “20×25 3M filters (1900 new EcoFOG 100)” filters tested (due to substances being captured by each filter, for example):

TABLE 42 Filters Weight (g) # Before After Δ m % W. Gain 1 306.6 446.2 139.6 45.5 2 306.1 422.4 116.3 38.0 3 304 386.1 82.1 27.0 4 306.2 346.5 40.3 13.2 5 304.4 318.1 13.7 4.5 6 305 3100 5 4.6 Total 1832.3 2229.3 397 21.7 Table 43 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (1900 new EcoFOG 100)” filters tested:

TABLE 43 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) DPA/M³ DPA/M³ (Times) Reduction 5 531.0 175.0 3.0 67.0 30 935.0 128.0 7.3 86.3 60 1023.0 138.0 7.4 86.5 90 903.0 139.0 6.5 84.6 119 946.0 137.0 6.9 85.5

FIG. 20 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (1900 new EcoFOG 100)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 2000 includes a plot 2010, which illustrate a percentage of weight gain of each “20×25 3M filters (1900 new EcoFOG 100)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 65 minutes in a first room and 80 in a second room.

Table 44 is a summary of the weight gain of the “20×25 3M filters (1900 new EcoFOG 100)” filters after being used for filtering both rooms (sequentially):

TABLE 44 Filters Weight (g) # Before After Δ m % W. Gain 1 308.58 530 221.42 71.8 2 309.97 499.6 189.63 61.2 3 309.74 460.1 150.36 48.5 4 310.56 424.4 113.84 36.7 5 307.53 380.3 72.77 23.7 6 309.12 347.7 38.58 12.5 Total 1855.5 2642.1 786.6 42.4 Table 45 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (1900 new EcoFOG 100)” filters tested in the first room:

TABLE 45 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 351.0 33.0 10.5 90.6 20 830.0 6.0 138.3 99.3 35 517.0 3.0 172.3 99.4 50 868.0 6.0 1447 99.3 65 534.0 17.0 31.4 96.8 Table 46 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (1900 new EcoFOG 160)” filters tested in the second room:

TABLE 46 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 5 249.0 5.0 49.8 98.0 20 1188.0 14.0 84.9 98.8 35 731.0 53.0 13.8 92.7 50 1108.0 38.0 29.2 96.6 65 949.0 50.0 19.0 94.7 80 858.0 276.0 3.1 67.8

FIG. 21 is a plot diagram that illustrates the efficiency of a “six new 3M filters (EcoFOG 160)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 2100 includes a plot 2110, which illustrate a percentage of weight gain of each “six new 3M filters (EcoFOG 160)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 118 minutes.

Table 47 is a summary of the weight gain of the “six new 3M filters (EcoFOG 160)” filters tested (due to substances being captured by each filter, for example):

TABLE 47 Filters Weight (g) # Before After Δ m % W. Gain 1 310.6 501.8 191.2 61.6 2 308.8 452.9 144.1 46.7 3 309.8 403.4 93.6 30.2 4 311.6 359.8 48.2 15.5 5 308.7 323.3 14.6 4.7 6 309.1 313.9 4.8 1.6 Total 1858.6 2355.1 496.5 26.7 Table 48 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “six new 3M filters (EcoFOG 160)” filters tested:

TABLE 48 Aerosol Analysis Sampling Time Pre-Filter mg After-Filter mg AI Reduction % (min) Pyr./M³ Pyr./M³ (Times) Reduction 6 413.0 1.0 413.0 99.8 60 289.0 2.0 144.5 99.3 118 4734.0 9.0 526.0 99.8

FIG. 22 is a plot diagram that illustrates the efficiency of a “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 2200 includes a plot 2210, which illustrate a percentage of weight gain of each “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 49 is a summary of the weight gain of the “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filters tested:

TABLE 49 Filters Weight (g) # Before After Δ m % W. Gain 1 313.04 833.24 520.2 166.2 2 312 577.42 265.42 85.1 3 312.8 477.33 164.53 52.6 4 310.76 393.93 83.17 26.8 5 312.25 388.6 26.35 8.4 6 314.65 328.98 14.33 4.6 Total 1875.5 2949.5 1074 57.3

FIG. 23 is a plot diagram that illustrates the efficiency in a second test of a “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter bank used in a thermo-fogging filtration system in accordance with embodiments of the present disclosure. Chart 2300 includes a plot 2310, which illustrate a percentage of weight gain of each “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filter of a filter bank (for example) used in an exemplary thermo-fogger filtration system having a total “fog” application time of 125 minutes.

Table 50 is a summary of the weight gain of the “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filters tested (due to substances being captured by each filter, for example):

TABLE 50 Filters Weight (g) # Before After Δ m % W. Gain 1 312.98 817.35 504.37 161.2 2 312.36 591.01 278.65 89.2 3 310.89 488.75 177.86 57.2 4 311.74 411.82 100.08 32.1 5 313.38 352.06 38.68 12.3 6 313.24 334.61 21.37 6.8 Total 1874.59 2995.6 1121.01 59.8 Table 51 is a summary of an analysis of the aerosol reduction in a thermo-fogging filtration system using “20×25 3M filters (2200 plus two inches of activated carbon EcoFOG 160 2L)” filters tested:

TABLE 51 Aerosol Analysis Pre-Filter EtOAC After-Fiber Filter After-Carbon Filter Sampling Relative EtOAC Relative EtOAC Relative % % % Time Concentration (No Concentration (No Concentration (No Reduction Reduction Reduction (min) m.u.) m.u.) m.u.) Fiber Carbon Total 35 567607 407245 38926 28.252294 90.44163 93.14209 65 235369 235103 30088 0.113014 87.2022 87.21667 95 169475 170857 68086 −0.81546 60.1503 59.82534 125 144186 371199 35583 −157.4446 90.41404 75.32146 The various exemplary embodiments described above are provided by way of illustration only and should not be construed to limit the claims attached hereto. Those skilled in the art will readily recognize various modifications and changes that could be made without following the example exemplary embodiments and applications illustrated and described herein, and without departing from the true spirit and scope of the following claims. 

What is claimed is:
 1. A method for filtration, comprising: arranging fruits in a substantially closed room having a volume of air; introducing post-harvest chemicals, and optionally, additional treatment substances, into an airstream with a thermo-fogger gun to generate air-borne treatment substances at a rate of up to 80 cubic feet per minute; introducing the airstream and the air-borne treatment substances into the volume of air of the substantially closed room to generate the dispersed air-borne substances; creating with a first fan a pressure between −0.25 and 0 inches water column upon a bank of at least six high particle-rated pleated fiber filters inducing an exhaust air current that flows from the substantially closed room into an exhaust port of the substantially closed room, wherein the exhaust air current includes the air-borne substances from the exhaust port and the filter bank captures at least around 95 percent of the air-borne treatment substances; and controlling the pressure of the substantially closed room by selectively varying the relative speed of the first fan and a second fan on the thermo-fogger gun.
 2. The method of claim 1, wherein ambient air is used as input to the thermo-fogger gun.
 3. A method for filtration, comprising: arranging vegetables in a substantially closed room having a volume of air; introducing post-harvest chemicals, and optionally, additional treatment substances, into an airstream with a thermo-fogger gun to generate air-borne treatment substances at a rate of up to 80 cubic feet per minute; introducing the airstream and the air-borne treatment substances into the volume of air of the substantially closed room to generate the dispersed air-borne substances; creating with a first fan a pressure between −0.25 and 0 inches water column upon a bank of at least six high particle-rated pleated fiber filters; and inducing an exhaust air current that flows from the substantially closed room into an exhaust port of the substantially closed room, wherein the exhaust air current includes the air-borne substances from the exhaust port and the filter bank captures at least around 95 percent of the air-borne treatment substances; and controlling the pressure of the substantially closed room by selectively varying the relative speed of the first fan and a second fan on the thermo-fogger gun.
 4. The method of claim 3, wherein ambient air is used as input to the thermo-fogger gun. 